TW201534201A - Power source device - Google Patents

Abstract

The present disclosure relates to a power source device. The power source device includes a housing, a battery unit, an inverter unit and a heat dissipating unit. The battery unit, the inverter unit, and the heat dissipating unit are received in the housing. The housing defines a first vent portion and a second vent portion. The first vent portion is positioned in an end surface of the housing, and the second vent portion is positioned in a side surface of the housing and is away from the end of the housing with the first vent portion. The heat dissipating unit includes a fan. The fan is positioned on the housing corresponding to a position of the second vent portion. The fan sucks air into the housing through the first vent portion and exhausts the air out of the housing through the second vent portion.

Description

Power supply unit

The present invention relates to a power supply device, and more particularly to a portable power supply device.

With the development of technology, portable power supply devices have become more and more popular. The power supply device generally includes components such as a battery pack, a circuit board, and a frequency converter. The above components generate a large amount of heat during operation. If the heat cannot be effectively dissipated, the life of the power supply device, stability of use, and safety are affected. Sex. Therefore, how to effectively dissipate heat from the power supply device has become an urgent problem to be solved.

In view of this, it is necessary to provide a power supply device capable of effectively dissipating heat.

A power supply device includes a housing, a battery unit, a frequency converter unit, and a heat dissipation unit. The battery unit, the inverter unit, and the heat dissipation unit are housed in the outer casing. The outer casing is provided with a first vent portion and a second vent portion, the first vent portion is located at an end of the outer casing, and the second vent portion is located at a side of the outer casing and An end portion of the first vent portion is formed away from the outer casing. The heat dissipating unit includes a fan, the fan is disposed at a position of the outer casing corresponding to the second vent, and the fan is configured to draw air into the outer casing from the first vent and The second vent exits the outer casing.

In contrast to the prior art, the power supply device opens the first vent portion and the second vent portion and provides a fan in the outer casing to carry heat inside the power supply device out of the outer casing by air flow Therefore, it can effectively dissipate heat, ensuring the service life and stability of the power supply unit.

Fig. 1 is a perspective view of a power supply device according to an embodiment of the present invention.

Figure 2 is an exploded view of the power supply unit of Figure 1.

3 is another perspective view of the power supply unit of FIG. 2.

4 is a schematic view showing the assembly of the power supply device of FIG. 2.

The present invention will be specifically described below with reference to the accompanying drawings.

1-4, a power supply device 100 according to an embodiment of the present invention includes a housing 10, a battery unit 20, a frequency converter unit 30, and a heat dissipation unit 40. The battery unit 20, the inverter unit 30, and the heat dissipation unit 40 are all housed in the outer casing 10.

The outer casing 10 includes a first end cap 11, a second end cap 12, a first assembled panel 13, a second assembled panel 14, a first side panel 15, and a second side panel 16. The first end cover 11, the second end cover 12, the first assembly board 13, the second assembly board 14, the first side panel 15, and the second side panel 16 are enclosed to form a housing. The battery unit 20, the inverter unit 30, and the housing space 101 of the heat dissipation unit 40.

The first end cover 11 serves as a power output end of the power supply device, and the first end cover 11 is provided with a power socket 111 and a power switch 112, and the power socket 111 is used for connecting an external power device (not shown) In the present embodiment, the power socket 111 is a three-hole socket, and the number of the power sockets 111 is three. It can be understood that the power socket 111 can also be a two-hole socket, a USB socket, or the like. Socket. The power switch 112 is configured to control an on-off connection between the power socket 111 and the battery unit 20, thereby controlling power output of the power supply device 100.

The second end cover 12 is disposed opposite to the first end cover 11 . The second end cover 12 is provided with a charging plug 121 electrically connected to the battery unit 20, and the charging plug 121 is used for connecting an external power source (not shown) to realize charging of the battery unit 20. A first vent portion 122 is defined in the second end cover 12. In the embodiment, the first vent portion 122 includes a plurality of elongated gaps 122a, and the plurality of elongated gaps 122a are evenly distributed along the same circumference. The arrangement is such that the flow distribution through the first vent portion 122 is uniform and the flow rate is uniform.

The first assembled board 13 and the second assembled board 14 are used to assemble and fix the battery unit 20. The first assembled board 13 includes a first bottom plate 131 and two first connecting plates 132. The first bottom plate 131 is substantially rectangular, and the first bottom plate 131 is formed with a plurality of first connecting portions 131a for connecting the battery unit 20. The first connecting plates 132 are respectively connected to two parallel sides of the first bottom plate 131, and the first connecting plates 132 extend perpendicularly to the same side of the first bottom plate 131. Each of the first connecting plates 132 is formed with a plurality of first engaging portions 132a. In the embodiment, the first engaging portions 132a are formed on the inner side of the corresponding first connecting plate 132. Specifically, the The first engaging portion 132a is formed by punching the first connecting plate 132. One of the first connecting plates 132 is provided with a second venting portion 132b, and the second venting portion 132b is located at an end of the first connecting plate 132 adjacent to the first end cover 11.

The second assembly board 14 has a shape similar to that of the first assembly board 13, and includes a second bottom board 141 and two second connecting boards 142 respectively connected to the second bottom board 141, the second bottom board A second connecting portion 141a for connecting the battery unit 20 and a handle portion 141b are formed on the 141, and the handle portion 141b is fixedly formed on an outer side surface of the second bottom plate 141. Each of the second connecting plates 142 is formed with a plurality of second engaging portions 142a respectively corresponding to the first engaging portions 132a. In the embodiment, the second engaging portions 142a are respectively formed corresponding to the second engaging portions 142a. The second connecting plate 142 is away from a side of the second bottom plate 141, and each of the second engaging portions 142a is substantially L-shaped.

In this embodiment, the distance between the second connecting plates 142 is smaller than the distance between the first connecting plates 132, so that the second connecting plate 142 can be inserted between the first connecting plates 132 and The second engaging portions 142a are respectively connected to the corresponding first engaging portions 132a. Of course, the first engaging portion 132a and the second engaging portion 142a can be interchanged, that is, the first engaging portion 132a is formed on the second connecting plate 142, and the second engaging portion The portion 142a is formed on the first connecting plate 132. In this case, the distance between the second connecting plates 142 needs to be larger than the distance between the first connecting plates 132.

The first side plate 15 and the second side plate 16 are used to shield the connected first connecting plate 132 and the second connecting plate 142. The first side plate 15 is located at a side of the first connecting plate 132 having the second vent portion 132b and the corresponding second connecting plate 142, and the first side plate 15 is provided with a corresponding one. The third vent portion 151 of the second vent portion 132b, when the first side plate 15 is in contact with the corresponding first connecting plate 132 and the second connecting plate 142, the third vent portion 151 is opposite The second vent portion 132b.

In this embodiment, the first assembly board 13 , the second assembly board 14 , the first side panel 15 , and the second side panel 16 are all made of a heat conductive metal material, such as aluminum, magnesium aluminum alloy, or the like. The heat inside the power supply device 100 can be effectively circulated.

The battery unit 20 includes a battery pack 21, a circuit control board 22 electrically connected to the battery pack 21, and a fixed frame 23. The battery pack 21 and the circuit control board 22 are fixedly coupled to the fixed frame 23. The battery pack 21 includes a plurality of cells 21a arranged in a matrix, and the battery cells 21a are formed in series and in parallel according to specific requirements to form the battery pack 21. In the embodiment, the battery cells 21a are lithium ion batteries. The core, each of the cells 21a is cylindrical. The circuit control board 22 is used to control charging and discharging of the battery pack 21 and integration and processing of electrical signals. The fixing frame 23 has a rectangular frame shape, the battery pack 21 is disposed inside the fixing frame 23, and the circuit control board 22 is fixed to a side portion of the fixing frame 23.

The frequency converter unit 30 is electrically connected to the battery unit 20 for adjusting an output voltage and a frequency of the battery unit. The frequency converter unit 30 includes a substrate 31 and a plurality of functional elements 32 disposed on the substrate 31. The inverter unit 30 is fixedly disposed in the outer casing 10 by two brackets 50. In the embodiment, the bracket 50 fixes the inverter unit 30 to the first assembly board 13. .

The heat dissipation unit 40 includes a heat pipe portion 41, a heat sink portion 42, and a fan 43. The heat pipe portion 41 includes a plurality of first heat pipes 411 and a second heat pipe 412. Each of the first heat transfer tubes 411 includes a first contact segment 411a, a second contact segment 411b, and a connecting segment 411c connecting the first contact segment 411a and the second contact segment 411b. In this embodiment, the first contact segment 411a and the second contact segment 411b are substantially parallel to each other, and the connecting segment 411c is substantially perpendicularly connected to the first contact segment 411a and the second contact segment 411b, and the The first contact segment 411a and the second contact segment 411b extend toward the same side of the connecting segment 411c. The length of the first contact segment 411a is substantially equivalent to the length of the battery unit 20, and the length of the second contact segment 411b is smaller than the length of the first contact segment 411a. Therefore, the first contact segment 411a, The first heat transfer tube 411 composed of the second contact portion 411b and the connecting portion 411c has a substantially L shape. The first heat transfer tube 411 is made of a highly thermally conductive material such as copper, aluminum or the like. Preferably, the first heat transfer pipe 411 is internally provided with a cooling liquid (not shown), and the coolant can be in the first contact section 411a and the second under the action of a capillary structure (not shown). The loop flows between the contact segments 411b to increase the efficiency of heat conduction.

The second heat pipe 412 has a similar function to the first heat pipe 411, and the second heat pipe 412 includes a first contact segment 412a, a second contact segment 412b, and a first contact segment. a connecting portion 412c of the second contact portion 412b, the first contact portion 412a and the second contact portion 412b are parallel to each other and extend away from each other, and the first contact portion 412a and the The second contact segments 412b are offset from each other by a distance in a direction perpendicular to the length direction of the two. The surface of the first contact segment 412a is provided with a metal connection layer 412d.

The heat sink portion 42 includes a first heat sink 421 and a second heat sink 422. The first heat sink 421 includes a first base 421a and a plurality of first fins 421b formed on the first base 421a. The first base 421a has a rectangular shape. The first fins 421b are arranged in parallel with each other, and a mounting groove 421c corresponding to the heat transfer tube portion 41 is formed between the first fins 421b. The second heat sink 422 is disposed on the inverter unit 30. Specifically, the second heat sink 422 is fixedly disposed on the substrate 31 of the inverter unit 30. The second heat sink 422 includes a second base 422a and a plurality of second fins 422b formed on the second base 422a.

The fan 43 is configured to discharge air in the outer casing 10 to dissipate heat from the battery unit 20 and the frequency converter unit 30. The fan 43 has a rectangular outer shape, and the fan 43 has the same size as the first base 421a toward the surface of the first heat sink 421.

The heat dissipation unit 40 further includes two fixing pieces 44 for fixing the fan 43 to the outer casing 10.

When assembled, the battery unit 20 and the inverter unit 30 are disposed on the first assembly board 13 of the outer casing 10; the first contact segments 411a of the first heat transfer tube 411 are respectively inserted adjacent to the battery unit 20 The second contact segments 411b are respectively inserted into the corresponding mounting slots 421c of the first heat sink 421; the first contact segments 412a of the second heat transfer tubes 412 are connected to the second heat sinks. On the bottom surface of the second base 422a of the sheet 422, a metal connection layer 412d of the first contact portion 412a and a bottom surface of the second base 422a are connected to each other by a thermal grease 412e; the second contact The segment 412b is inserted into the corresponding mounting groove 421c; the fan 43 is attached to the bottom surface of the first base 421a, and the fixing piece 44 fixes the fan 43 and the first base 421a therebetween. At the same time, the fixing piece 44 fixes the fan 43 to the position of the first assembly board 13 corresponding to the second vent portion 132b; the first assembly board 13 and the second assembly board 14 Interlocking with each other, the first engaging portion 132a and the corresponding first The two engaging portions 142a are engaged with each other; the first side plate 15 and the second side plate 16 are respectively disposed on the two sides of the first assembled board 13 and the second assembled board 14 after the connection, and the third air vent The portion 151 is opposite to the second vent portion 132b; the first end cover 11 and the second end cover 12 are respectively disposed at the two ends of the first assembled board 13 and the second assembled board 14 after the connection .

When the power supply device 100 is in operation, heat generated by the battery unit 20 is conducted from the first heat pipe 411 to the first heat sink 421, and heat generated by the inverter unit 30 is generated from the second heat sink. 422 and the second heat transfer tube 412 are conducted to the first heat sink 421, the fan 43 is turned on, and air enters the inside of the outer casing 10 from the first vent portion 122 and is under the action of the fan 43 Through the battery unit 20 and the inverter unit 30 to the first heat sink 421, in the process, air can take away some of the heat generated by the battery unit 20 and the inverter unit 30, and then, The air is discharged from the outer casing 10 by the fan 43, and at the same time, the air carries heat conducted to the first heat sink 421 out of the outer casing 10. The design of the first vent portion 122 and the second vent portion 132b can increase the stroke of air within the outer casing 10 and can sufficiently remove heat from the outer casing 10.

The power supply device 100 collects the heat generated by the battery unit 20 and the inverter unit 30 by the heat dissipating unit 40, and concentrates the heat on the first heat sink 421, and then the fan 43 The heat is discharged outside the outer casing 10, thus having a more effective heat dissipation effect, ensuring the service life and stability of the power supply device 100.

In summary, the present invention has indeed met the requirements of the invention patent, and has filed a patent application according to law. However, the above description is only a preferred embodiment of the present invention, and it is not possible to limit the scope of the patent application of the present invention. Equivalent modifications or variations made by persons skilled in the art in light of the spirit of the invention are intended to be included within the scope of the following claims.

100‧‧‧Power supply unit

10‧‧‧ Shell

11‧‧‧First end cap

111‧‧‧Power socket

112‧‧‧Power switch

12‧‧‧Second end cap

121‧‧‧Charging plug

122‧‧‧First vent

122a‧‧‧Slim gap

13‧‧‧First assembled board

131‧‧‧First floor

131a‧‧‧First connection

132‧‧‧First connecting plate

132a‧‧ First First Joint Department

132b‧‧‧second vent

14‧‧‧Second assembled board

141‧‧‧second bottom plate

141a‧‧‧Second connection

141b‧‧‧Handle

142‧‧‧Second connection plate

142a‧‧‧Second Jointing Department

15‧‧‧First side panel

151‧‧‧ Third vent

16‧‧‧Second side panel

101‧‧‧ accommodating space

20‧‧‧ battery unit

21‧‧‧Battery Pack

22‧‧‧Circuit Control Board

23‧‧‧Fixed frame

21a‧‧‧ batteries

30‧‧‧Inverter unit

31‧‧‧Substrate

32‧‧‧Functional components

40‧‧‧heating unit

41‧‧‧Heat pipe department

411‧‧‧First heat pipe

411a‧‧‧First contact segment

411b‧‧‧second contact section

411c‧‧‧Connection section

412‧‧‧Second heat pipe

412a‧‧‧First contact segment

412b‧‧‧second contact section

412c‧‧‧ Connection section

412d‧‧‧Metal connection layer

412e‧‧‧thermal paste

42‧‧‧Heats Department

421‧‧‧First heat sink

421a‧‧‧First base

421b‧‧‧First fin

421c‧‧‧Installation slot

422‧‧‧second heat sink

422a‧‧‧Second base

422b‧‧‧second fin

43‧‧‧Fan

50‧‧‧ bracket

no

100‧‧‧Power supply unit

11‧‧‧First end cap

111‧‧‧Power socket

112‧‧‧Power switch

12‧‧‧Second end cap

121‧‧‧Charging plug

122‧‧‧First vent

122a‧‧‧Slim gap

13‧‧‧First assembled board

131‧‧‧First floor

131a‧‧‧First connection

132‧‧‧First connecting plate

132a‧‧ First First Joint Department

132b‧‧‧second vent

14‧‧‧Second assembled board

141‧‧‧second bottom plate

141a‧‧‧Second connection

141b‧‧‧Handle

142‧‧‧Second connection plate

142a‧‧‧Second Jointing Department

15‧‧‧First side panel

151‧‧‧ Third vent

16‧‧‧Second side panel

101‧‧‧ accommodating space

20‧‧‧ battery unit

21‧‧‧Battery Pack

22‧‧‧Circuit Control Board

23‧‧‧Fixed frame

21a‧‧‧ batteries

30‧‧‧Inverter unit

31‧‧‧Substrate

32‧‧‧Functional components

40‧‧‧heating unit

41‧‧‧Heat pipe department

411‧‧‧First heat pipe

411a‧‧‧First contact segment

411b‧‧‧second contact section

411c‧‧‧Connection section

412‧‧‧Second heat pipe

412a‧‧‧First contact segment

412b‧‧‧second contact section

412c‧‧‧ Connection section

412d‧‧‧Metal connection layer

412e‧‧‧thermal paste

42‧‧‧Heats Department

421‧‧‧First heat sink

421a‧‧‧First base

421b‧‧‧First fin

421c‧‧‧Installation slot

422‧‧‧second heat sink

422a‧‧‧Second base

422b‧‧‧second fin

43‧‧‧Fan

50‧‧‧ bracket

Claims (10)

A power supply device comprising a casing, a battery unit, a frequency converter unit and a heat dissipation unit, wherein the battery unit, the frequency converter unit and the heat dissipation unit are housed in the outer casing, and the improvement is that the outer casing a first vent portion and a second vent portion, the first vent portion being located at an end of the outer casing, the second vent portion being located at a side of the outer casing and away from the The outer casing is formed with an end of the first vent portion, the heat dissipating unit includes a fan, the fan is disposed at a position of the outer casing corresponding to the second vent, and the fan is used for air The first vent is drawn into the outer casing and the outer casing is discharged from the second vent. The power supply device of claim 1, wherein the outer casing comprises a first end cover, a second end cover, a first assembled panel, and a second assembled panel, the battery unit, the frequency converter unit And the heat dissipation unit is received in a space formed by the first end cover, the second end cover, the first assembly board, and the second assembly board, wherein the first vent opening is opened in the The second vent opening is formed on the first assembly panel. The power supply device of claim 2, wherein the first vent portion includes a plurality of elongated gaps, the plurality of elongated gaps being evenly arranged in a radial direction of the same circumference. The power supply device of claim 2, wherein the first assembly board comprises a first bottom plate and two first connecting plates respectively connected to opposite sides of the first bottom plate, the second assembled board a second bottom plate and two second connecting plates respectively connected to opposite sides of the second bottom plate, the first connecting plates are respectively connected to the second connecting plate, and the second ventilation holes are formed on One of the first connecting plates. The power supply device of claim 4, wherein each of the first connecting plates is formed with a plurality of first engaging portions, and each of the second connecting plates is formed with a plurality of corresponding ones respectively corresponding to the first card The second engaging portion of the joint portion is respectively engaged with the corresponding second engaging portion. The power supply device of claim 5, wherein the first engaging portion is formed on an inner side surface corresponding to the first connecting plate, and the second engaging portion is formed on the corresponding second connecting plate away from the second connecting plate a side of the second bottom plate, a distance between the second connecting plates is smaller than a distance between the first connecting plates, the second connecting plate is inserted between the first connecting plates and the first connecting plate is The two engaging portions are respectively connected to the corresponding first engaging portions. The power supply device of claim 5, wherein each of the second engaging portions is L-shaped. The power supply device of claim 4, wherein the outer casing includes a first side plate and a second side plate, and the first side plate and the second side plate are respectively disposed outside the first connecting plate, A third vent portion corresponding to the second vent portion is opened on the first side plate, and the third vent portion faces the second vent portion. The power supply device of claim 8, wherein the first assembled board, the second assembled board, the first side panel, and the second side panel are each made of a thermally conductive metal material. The power supply device of claim 4, wherein the second bottom plate is formed with a handle portion.